Atmospheric aerosols are tiny particles that scatter and absorb sunlight but also influence climate indirectly through their role in cloud formation. One of the largest sources of aerosols is sea spray which is produced over the world’s oceans. Understanding how these particles take up water from the atmosphere, their so-called hygroscopicity, is important because it determines how much sunlight they reflect and how well they can form clouds.
“It is widely understood that aerosols have a net cooling effect on climate, counteracting the warming caused by greenhouse gases. However, the magnitude of this cooling is highly uncertain, in part due to knowledge gaps in how natural aerosol particles interact with solar radiation and clouds,” says Matt Salter, researcher at ACES, and co-author of the study.
Sea spray is a complex mixture of inorganic salts, organic material present in the ocean and living organisms such as bacteria, viruses and fungi. The ability of the inorganic component of sea spray particles to take up water has been the focus of this international study where a large suite of well-controlled laboratory experiments has shown, for the first time, that the hygroscopicity of the inorganic component of sea spray is significantly lower than pure sodium chloride, a substance routinely used to describe their hygroscopicity in climate models.
“All numerical models are simplified reflections of reality which require approximations. It was previously thought that sodium chloride was a good approximation for the hygroscopicity of the inorganic fraction of sea spray. We have now shown that the hygroscopicity of pure inorganic sea spray particles is significantly lower than sodium chloride. This finding has implications for the role of sea spray aerosols in climate, especially on how they interact with solar radiation, ” says Paul Zieger, assistant professor at ACES and co-author of the study.
Using models, the authors were able to show that the reduced hygroscopicity of sea spray means that these particles will grow less and reflect less sunlight than previously thought. However, the picture may be more complicated.
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Image credit: ACES
